Dark Matter with AMS-02 Aachen , 17 Ju ly 2003 Mariusz Sapinski

1. Dark Matter with AMS-02 Aachen, 17 July 2003 Mariusz Sapinski (Groupe d’ Astroparticules de Montpellier, CNRS/IN2P3) on behalf of AMS collaboration AMS, M.Sapinski

2. AMS-02 • Cosmic Rays : p, D, He, C, …,e+, e-,  Will Collect ~1010 CRs in Near-Earth Orbit from few GV to few TV • Direct Search for Cosmic Anti-matter • Indirect Searches for Dark Matter • Other searches: strangelets, Primordial Black Holes, Quasars, -Astronomy, ... A Particle Physics Experiment on the International Space Station for 3 Years (Launch October 2005). AMS, M.Sapinski

3. AMS-02 on ISS HEP – NASA experiment AMS, M.Sapinski

4. Detector AMS, M.Sapinski

5. AMS-02 Completeness AMS, M.Sapinski

6. Performances Angular and Energy resolution for gs Overall proton/ suppression factor > 105 AMS, M.Sapinski

7. AMS collaboration ~ 200 scientists + dozens of contractors U. of Aarhus (DK); Academia Sinica (Taiwan); U. of Bucharest (RO); Chinese Academy of Sciences, Inst. of High Energy Physics IHEP (Beijing); Chinese Academy of Sciences, Inst. of Electrical Engineering IEE (Beijing); Centro de Investigaciones Energeticas, Medioambientales y Tecnologicas CIEMAT (Madrid, ES); Chung Shan Inst. of Science and Technology CSIST (Taiwan); EHWA Women's University (Seoul, KR) ETH Zurich (CH); Florida A&M U. (Tallahassee, FL); U. of Geneva (CH); Helsinki U. of Technology (FI); INFN Bologna & U. Bologna (IT); INFN Milano (IT); INFN Perugia, (IT); & U. Perugia (IT); INFN Pisa & U. Pisa (IT); INFN Roma & U. Roma (IT); INFN Siena & U Siena (IT); Inst. Superior Technico (Lisbon, PT); Inst. di Ricerca sulle Onde Elettromagnetiche IROE (Florence, IT); Inst. des Sciences Nucleaires de Grenoble ISN (FR); Inst. for Theoretical and Experimental Physics ITEP (Moscow, RU), Jiao Tong U. (Shanghai); Johns Hopkins U. (Baltimore, US); U. of Karlsruhe (DE); Kurchatov Institute (Moscow, RU); Kyungpook National University CHEP (Taegu, KR); Laboratoire d'Annecy-le-Vieux de Physique des Particules LAPP (FR); Laboratório de Instrumentaço e Física Experimental de Partículas LIP (Lisbon, PT); U. Maryland (College Park, US); Max Planck Inst. (Garching, DE) ; Massachusetts Inst. of Technology MIT (Cambridge, US); U. Montpellier (FR); Moscow State University (RU), Nat'l Aerospace Laboratory NRL (Amsterdam, NL); U. Nacional Autonoma de Mexico (MX); Nat'l Space Program Office (Taiwan); Nat'l Central University NCU (Taiwan); Nat'l Inst. for Nuclear Physics and High Energy Physics NIKHEF (Amsterdam, NL) I. Physikalisches Inst., RWTH Aachen (DE); III. Physikalisches Inst., RWTH Aachen (DE); Southeast U. (Nanjing); U. of Turku (FI); Yale U. (New Haven, US); Lockheed Martin, USA; Space Cryomagnetics LTD, UK; Arde, Inc., USA; CAEN Aerospace, IT; Carlo Gavazzi Space SpA, IT; ISATECH Engineering GmbH, DE; OHB GmbH, DE; Linde; NASA; ESA AMS, M.Sapinski

8. Cosmic Rays • Protons Dominant Component • He 5% of P flux at10 GeV • p- ~ 10-3 % of P Flux • D-, heavier anti-nuclei unobserved • Power Spectra: Supernova Shock Acceleration • Propagation Magnetic Fields • Cosmic Rays  atmospheric  Astroparticle studies embedded in Cosmic Ray Physics AMS, M.Sapinski

9. Indirect Dark Matter Search • Universe Matter budget – 90 % is Dark  non baryonic • Structure formation – Dark Matter is Cold (CDM) • SUSY provides an excellent WIMP candidate – neutralino : 01 0101  qq- , W+W-, H+H-, ...  p- ,anti-D ,  , e+, +X • Completeness of AMS-02: • p- : Excess at Energy of a few GeV • D- : Excess Below 1 GeV • e + :Structure in Spectra above few GeV •  :Energy Spectra differ from “power laws”, or  line detection 0101 , Z AMS, M.Sapinski

10. Anti–protons In case of a SUSY contribution at high energy, this could be measured Ullio (1999) , m ~ 900 GeV Tertiary background E (GeV) Full 3 yr (MC) AMS sensitivity without considering any DM signature. AMS, M.Sapinski

11. Cosmic-Ray Positrons Heat Data : a bump in energy at 7 GeV, no standard astrophysical interpretation of e+/e- energy distribution • Precise data extended to higher energies will be provided by AMS MSSM simulation for AMS-02 need high “boost factors” m  336 GeV m  130.3 GeV AMS, M.Sapinski

12. Anti-Deuterons MSSM : Donato, Fornengo, Salati, 1999 Promising for long exposures large acceptance in space AMS, M.Sapinski

13. Dark Matter -  ray case 3C279 Cygnus Region Vela Geminga Crab PKS 0528+134 LMC Cosmic Ray Interactions With ISM PSR B1706-44 PKS 0208-512 EGRET map E>100 MeV AMS, M.Sapinski

14. Dark Matter -  ray case Detection rate (source) : N v2(r) dl() d m2     LoS SUSY Astrophysics • diffuse D M : galactic as  , e+ , p-, D-, Direct Detection extragalactic • source D M : - Galactic Centre(G. C.) - Nearby Spiral Galaxies : e. g. M31 - Dwarf Spheroidals : e. g. DRACO - Globular Clusters :  - centauris, Palomar13  Enhancement factors from cuspy halos, clumpiness or/and SBH AMS, M.Sapinski

15. -rays from Galactic Centre mSUGRA simulations for large m0 G. C. Navarro-Frenk-White profile with various parameters “wild scan”, flux above 3 GeV NFW, optimistic NFW, pessimistic Benchmark AMS, M.Sapinski

16. Benchmark Models (mSUGRA models proposed by Battaglia et al, 2002) Numbers of photons expected in AMS-02 in 1 year from GC AMS, M.Sapinski

17. Summary • AMS-02 will provide data from October 2005 and at least 3 years on • The completeness of AMS-02 detector will allow to measure simultaneously the Astroparticle Signals and Cosmic Backgrounds • AMS-02 will probe • Dark Matter content in various channels (p-, D-,e+, ) • Barzon Asymmetry • Cosmic Rays and -Astrophysics (not covered here) • Exotics, strangelets, PBHs, and unexpected … AMS, M.Sapinski